EP0410959A1 - Device for treating waters in tanks - Google Patents

Abstract

A device for treating, in particular aerating and thoroughly mixing, waters in a tank (1) has at least one container (2), preferably several containers, which is or are arranged on the tank edge, closed at its or their lower end (3) and provided at its or their upper end with an overflow orifice (5) below the liquid level (4) in the tank (1). The containers (2) contain aeration means through which the liquid in the container (2) is aerated. This liquid is fed to any container (2) from the tank (1) via at least one suction pipe (8) which enters the interior of the container (2) below the aeration means (6) and whose suction orifice (9) is arranged a considerable distance away from the container wall. The air passed into the container (2) rises and therefore gives rise to a flow in the container (2), by means of which liquid is sucked into the container (2) via the suction pipe (8), resulting in flow conditions in the tank (1) which produce complete and homogeneous aeration and thorough mixing of the tank contents. <IMAGE>

Description

The invention relates to a device for the treatment of waters located in basins, in particular of waste water, landfill juices, fish waters, with at least one container, which is arranged sunk in the basin, preferably cylindrical with an essentially vertical axis, the upper end of which has at least one overflow opening and in which a ventilation device is arranged. The term "basin" is understood to mean both artificial and natural basins of various shapes, for example also fish ponds, the artificial basins being open or closed at the top.

It is often necessary to aerate the waters in such pools. For example, ventilation of a primary clarifier for waste water or aeration of pools containing landfill juices is necessary so that aerobic pretreatment of the pool contents takes place there. For this purpose, it is also necessary to circulate the pool contents. In fish ponds, ventilation is necessary to ensure the necessary oxygen for the fish. In this case, too, it is advisable to circulate the water in order to ensure uniform aeration of the entire water content and to simulate a movement of the water in fish living in flowing waters.

It is already known to suspend recessed aeration devices in the basin on floats arranged on the water surface or on a bridge spanning the basin or at least part of the same and to move them so that different areas of the basin are successively aerated. The disadvantage of this arrangement is that not only a complex construction for supporting the ventilation devices, but also devices for moving the ventilation devices within the basin must be provided. Another major disadvantage is that there is always only partial ventilation of the pool contents at those points that are immediately adjacent to the ventilation devices.

It is also known to provide a tube through which the contents of the pool flow, to which water is supplied under pressure at one point via a nozzle, an air supply line opening in the region of the nozzle, so that air is entrained by the pressurized water supply, which is in contact with water blended. Another similar known one Embodiment is likewise in a basin a tube open at the upper and lower ends with a substantially vertical axis sunk, to which a gas under pressure is supplied via a line which opens laterally into the tube wall from a tank (EP-A-0 033 407) . As a result, the liquid in the basin rises up inside the pipe and sinks down again in the circuit immediately outside the pipe. In all of these known arrangements, therefore, a movement of the pool contents and ventilation of the pool takes place only within the tube and in the immediate vicinity thereof.

It is an object of the present invention to provide a device for the treatment of waters located in pools, which avoids the disadvantages mentioned, works simply and inexpensively, and ensures extensive ventilation of the pool contents. To achieve this object, the invention proposes that the lower end of the container is closed and that at least one suction line opens into the container below the ventilation device, the suction opening of which is arranged at a distance from the container wall below the liquid level of the basin. Via this suction line, the liquid in the basin can penetrate into the container, which is closed at the bottom, where it is mixed with air via the ventilation device, thus aerated. By mixing with air, the liquid becomes lighter, therefore rises within the container and emerges from the overflow opening. This creates a flow from bottom to top in the container, which causes liquid to flow from the basin into the container via the suction line. The liquid in the basin thus flows in a large-scale circuit, namely upwards in the container, where it emerges through the overflow opening; and then down into the basin, where it enters the suction line through the suction opening and from there into the container. Since the suction opening is now arranged at a distance from the container wall, this flow not only achieves mixing and ventilation in the immediate vicinity of the container, but rather extensive, intensive ventilation and mixing of the tank contents is achieved, at least in that area between the overflow opening of the tank Container and the suction opening of the suction line guaranteed. The device according to the invention thus enables intensive ventilation with a small number of ventilation devices in relation to the pool size Aeration and mixing of the pool contents with great homogeneity, without it being necessary to move the aeration devices within the pool. When using the device according to the invention, there is a large circulation quantity of the liquid in the basin per unit of time with a small power requirement, so that not only is energy saved, but also the basin size can be selected smaller when used in wastewater treatment plants, as a result of the intensive aeration of the basin contents the batch-wise removal can take place in shorter time intervals.

According to a preferred embodiment of the invention, the overflow opening arranged at the upper end of the container is provided below the liquid level of the basin, so that the liquid rising in the container emerges in the region of the liquid level of the basin, but below this liquid level, causing undesirable foam formation in the region of the Liquid level can at least be reduced.

A cover plate is expediently provided at a distance above the overflow opening which is preferably formed by the open top of the container, but below the liquid level. This cover plate causes a deflection in an approximately horizontal direction when the liquid which rises approximately vertically in the container and mixed with air emerges from the overflow opening, so that this liquid first moves in the desired manner along the liquid level before it sinks again in the basin. This also prevents undesirable foam formation in the area of the liquid level. Finally, the arrangement of this cover plate has the advantage that the flow rate remains essentially constant with a constant distance of the cover plate from the overflow opening even with different immersion depths of the container.

The suction opening of the suction line is preferably provided in the area of the bottom of the basin, so that the liquid located in this bottom area is also intensively aerated and circulated.

According to a preferred embodiment of the invention, the ventilation device can have a disk-shaped impeller, which is driven by a submersible motor for a rotational movement and is arranged approximately horizontally below the motor, the upper side of which covers an annular opening in an air duct which is connected to the atmosphere via an air line, and the latter Bottom with about is provided radially extending ribs and is covered on the circumference by a cover ring, wherein a gap is kept free between the edge of the annular opening of the air duct and the top of the impeller and between the cover ring and the bottom of the impeller. With this design of the ventilation device, the liquid in the container is sucked in centrally on the underside of the impeller and flung outwards through the ribs, where it emerges through the gap between the underside of the impeller and the cover ring, air being simultaneously sucked in through the air line and through the gap between the top of the impeller and the edge of the annular opening of the air duct is conveyed to the outside. At the end of the two adjacent gaps, the air mixes intimately with the liquid, so that an excellent complete aeration of this liquid is effected. Because the aerated liquid is conveyed radially outwards, the entire contents of the container are evenly aerated.

The outer diameter of the cover ring is preferably larger than the diameter of the impeller, which results in good guidance of the liquid in the region of the gap and the ventilation is improved.

The ribs expediently run in an arc shape on the underside of the impeller and at least 8, preferably between 8 and 20, ribs are provided.

Such a ventilation device can be arranged at most 4 m below the liquid level, since otherwise the suction effect is not sufficient to suck in a sufficiently large amount of air via the air line. Particularly in the case of deeper pools and therefore correspondingly longer tanks, it is therefore advantageous if the ventilation device is formed by an air injection nozzle which is connected to a compressed air source.

According to a preferred embodiment of the invention, the container or a plurality of containers is preferably arranged at the edge of the basin, the suction lines for the liquid in the basin running approximately towards the center of the basin, that is to say approximately radially in the case of a cylindrical basin. This training not only results in complete and uniform ventilation and mixing of the entire pool contents, but also enables easy maintenance of the ventilation devices, since these are accessible from the pool edge Lich and no bridge structures or the like. are required to access the ventilation equipment.

In particular when using the device according to the invention for raw water, undesirable foam formation frequently occurs in the area of the liquid level of the basin. In order to remove this foam, a device for destroying the foam which forms on the surface of the liquid can be provided in the region of the liquid level of the basin. According to a preferred embodiment of the invention, this device has a disc-shaped impeller which is driven by a submersible to perform a rotational movement, approximately horizontally in the region of the boundary between the liquid and the foam-like phase of the liquid, the surface of which is provided with approximately radial ribs . This device for destroying the foam forming on the surface of the liquid thus corresponds in a constructive manner, apart from the missing cover ring and the lack of air conduit to the ventilation device described above, but is reversed in the basin, so that with this device the tread is above the Submersible is located. In addition, the number of ribs on the impeller in this device is less than the number of ribs on the impeller in the ventilation device and is preferably less than half the number of these ribs in the ventilation device. By means of this device for destroying the foam, the foam is sucked centrally from the impeller and conveyed radially outward, where it liquefies and is pressed downwards where it mixes with the liquid. This effectively removes the foam.

The ribs on the upper side of the impeller also expediently run in an arc.

In the drawing, the invention is illustrated schematically using an exemplary embodiment. 1 shows a cross section through a device according to the invention arranged in a basin along the line II in FIG. 2 and FIG. 2 shows a plan view in the direction of the arrows II in FIG. 1. FIG. 3 shows a side view, partly in section 4 shows a view in the direction of arrow IV in FIG. 2. FIG. 5 shows a side view, partly in section, of a device for destroying the foam forming on the surface of the liquid in the basin, and FIG .6 represents a view in the direction of arrow VI in Fig.5.

In a basin 1, which is shown in the drawing as an artificial basin, but can also be a natural basin, for example a pond, there is at least one cylindrical container 2 with an essentially horizontal axis. In the illustrated embodiment, four such containers 2 are shown. The number of containers can vary depending on the size of the pool. Each container 2 is closed at its lower end by a bottom 3, which preferably rests on the bottom of the basin 1, and has at its upper end at least one overflow opening 5 arranged below the liquid level 4 of the liquid in the basin 1, which in the simplest case is formed by the open top of the container 2. However, the container 2 can also end above the liquid level 4, which is advantageous for carrying out revision work, since the interior of the container is then more easily accessible. In this case, however, 4 overflow openings 5 must be arranged in the container wall below the liquid level.

At a distance above the open end of the container 2 forming the overflow opening 5, but below the liquid level 4, a cover plate 11 is provided, through which the liquid emerging from the overflow opening 5 is deflected approximately parallel to the liquid level 4 and an approximately constant flow rate the liquid is ensured at different immersion depths of the container 2.

Inside each container 1 there is a ventilation device 6, which is explained in more detail below. The ventilation device 6 is supported by struts 7 or the like on the container wall and is provided with an air line 37 which ends above the liquid level 4 and is thus connected to the atmosphere.

Below the ventilation device 6, at least one suction line 8 formed by a flanged tube opens into the interior of the container 3, the suction opening 9 of which is located at a distance of approximately 5 to 6 m from the container wall, depending on the size of the basin.

The containers 2 are expediently provided at the edge of the pool and the suction lines extend in the direction of the center of the pool, that is to say radially inwards in the case of a cylindrical pool. The arrangement of the container 2 on the pool edge has the advantage that they are easily accessible for maintenance purposes. By means of the ventilation device 6, the air sucked in via the air line 37 is mixed with the liquid entering the interior of the container 2 via the suction line B, this liquid thus being aerated. This mixture with air makes the liquid lighter and thus rises in the container 2 until it emerges from the container via the overflow opening 5. Due to this upward flow of the liquid in the container 2, however, liquid is sucked into the container 2 via the suction line 8, as a result of which a liquid flow in the direction of the suction opening 9 is formed in the basin 1. Since this suction opening 9 is at a considerable distance from the container 2, the flow in the basin 1 not only forms in the immediate vicinity of the container 2, but extends over a large area of the basin volume. Thus, with a stationary ventilation device 6, there is extensive ventilation and mixing of the pool contents.

Particularly when there is raw water in the basin 1 which is to be aerated, foam forms on the surface in a disruptive manner, which has to be removed. For this purpose, a device 10 for destroying the foam which forms on the surface of the liquid can be provided in the region of the liquid level 4 of the basin 1, the structure of which is explained in more detail below.

The ventilation device 6 shown in FIGS. 3 and 4 has a housing 33 in which a submersible motor is arranged, the shaft of which is designated by 34. A disk-shaped impeller 35 is driven by the shaft 34. In the lower part of the housing 33 there is an air duct 36 which is connected to the atmosphere via the air line 37. This air line 37 thus ends above the liquid level of the basin 1. At the bottom of the air channel 36 there is an annular opening 38 which is covered by the top 39 of the impeller 35 in such a way that between the edge of this annular opening 38 and the top 39 Gap 40 is kept clear.

On the underside 41 of the impeller 35, there are ribs 42 which are curved and approximately radial. Below the impeller 35 there is a cover ring 43 at such a distance from the underside 41 that a gap 44 is also kept free between this underside and the cover ring 43.

The outer diameter of the cover ring 43 is larger and the inner diameter of the cover ring 43 is smaller than the diameter of the impeller 35.

The number of ribs 42 depends on the depth at which the ventilation device is located in the container 2. As a rule, between 8 and 20 such ribs 42 are provided, the number of ribs decreasing with increasing depth.

The ventilation device 6 according to the invention works as follows:
During the rotation of the impeller 35, on the one hand, the liquid located in the container 2 is sucked in centrally by the ribs 42 provided on the underside 41 and conveyed in the direction of the circumference of the impeller, on the other hand, air is sucked in via the air line 37, which emerges from the gap 40 emerges and there mixes intimately with the liquid thrown out of the gap 44, so that excellent ventilation of this liquid is achieved with simultaneous circulation. The two gaps 40, 44 ensure good suction for both the liquid and the air.

The device 10 shown in FIGS. 5 and 6 for destroying the foam forming on the surface of the liquid in the basin 1 has a housing 45, in which a submersible motor is likewise accommodated, the shaft 46 of which also drives a disk-shaped impeller 47, which in this device is located above the submersible motor, approximately horizontally in the region of the boundary between the liquid and the foam-like phase of the substrate. The ribs 48 are provided on the top 49 of the impeller and also extend radially outward in an arc shape. However, the number of ribs 48 in this device is less than the number of ribs 42 of the ventilation device 6 and is preferably less than half.

On the top 49 of the impeller 47, which in this device for destroying the foam is not covered by a cover ring, the foam forming on the surface of the liquid in the basin 1 is effectively destroyed in that the foam is sucked into the center of the impeller 47 and is promoted towards the circumference of the impeller where it is liquefied.

Claims (13)

1. Device for the treatment of water in basins (1), in particular of waste water, landfill juices, fish waters, with at least one sunk in the basin (1), preferably cylindrical, with a substantially vertical axis, container (2), the upper end of which Has at least one overflow opening (5) and in which a ventilation device (6) is arranged, characterized in that the lower end (3) of the container (2) is closed and that in the containers (2) below the ventilation device (6) at least a suction line (8) opens, the suction opening (9) of which is arranged at a distance from the container wall below the liquid level (4) of the basin. 2. Device according to claim 1, characterized in that the overflow opening (5) arranged at the upper end of the container (2) is provided below the liquid level (4) of the basin (1). 3. Apparatus according to claim 1 and 2, characterized in that a cover plate (11) is provided at a distance above the overflow opening which is preferably formed from the open end of the container (2), but below the liquid level (4). 4. Apparatus according to claim 1, 2 or 3, characterized in that the suction opening (9) of the suction line (8) is provided in the region of the bottom of the basin (1). 5. Device according to one of claims 1 to 4, characterized in that the ventilation device (6) has a disc-shaped impeller (35) driven by a submersible motor for a rotational movement, arranged approximately horizontally below the motor, the upper side (39) of which has an annular opening (38) covers an air duct (36), which is connected to the atmosphere via an air line (37), and whose underside (41) is provided with approximately radial ribs (42) and is covered on the circumference by a cover ring (43) , a gap (40.) between the edge of the annular opening (38) of the air duct (36) and the top (39) of the impeller (35) and between the cover ring (43) and the bottom (41) of the impeller (35) , 41) is kept free. 6. The device according to claim 5, characterized in that the outer diameter of the cover ring (43) is larger than the diameter of the impeller (35). 7. The device according to claim 5, characterized in that the ribs (42) on the underside (41) of the impeller (35) extend arcuately. 8. The device according to claim 5,6 or 7, characterized in that at least 8, preferably between 8 and 20, ribs (42) are provided. 9. Device according to one of claims 1 to 4, characterized in that the ventilation device (6) is formed by an air injection nozzle connected to a compressed air source. 10. Device according to one of claims 1 to 9, characterized in that the container (2), preferably a plurality of containers, is or are arranged at the edge of the basin (1), and in that the suction lines (8) for the in the basin ( 1) Any liquid present should run towards the center of the pool (1). 11. Device according to one of claims 1 to 10, characterized in that in the region of the liquid level (4) of the basin (1) a device (10) is provided for destroying the foam forming on the surface of the liquid. 12. The apparatus according to claim 11, characterized in that the device (10) for destroying the foam forming on the surface of the liquid (10) driven by a submersible to a rotational movement, approximately horizontally in the region of the boundary between the liquid and the Foam-shaped phase of the substrate above the motor arranged disc-shaped impeller (47), the top (49) is provided with approximately radial ribs (48). 13. The apparatus according to claim 12, characterized in that the ribs (48) on the top (49) of the impeller (47) extend in an arc.

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